Imaging device

ABSTRACT

An imaging device according to the present disclosure includes: a counter electrode; a first pixel electrode facing the counter electrode; a second pixel electrode facing the counter electrode; a third pixel electrode facing the counter electrode; a photoelectric conversion layer sandwiched between the first pixel electrode, the second pixel electrode, and the third pixel electrode, and the counter electrode; a first signal detection circuit electrically connected to the first pixel electrode; a second signal detection circuit electrically connected to the second pixel electrode; a first switching element connected between the third pixel electrode and the first signal detection circuit; and a second switching element connected between the third pixel electrode and the second signal detection circuit.

BACKGROUND

1. Technical Field

The present disclosure relates to an imaging device.

2. Description of the Related Art

Image sensors using photoelectric conversion have been in widespread use. There is a need for dynamic range expansion in the field of image sensors.

Japanese Unexamined Patent Application Publication No. 2007-288522 discloses a solid-state imaging device 100 having high-sensitivity elements 102a and low-sensitivity elements 102b different in photodiode light-receiving area from each other arrayed in a light-receiving region (FIG. 2). The solid-state imaging device 100 in Japanese Unexamined Patent Application Publication No. 2007-288522 performs shooting using different exposure times for the high-sensitivity elements 102a and the low-sensitivity elements 102b. A wide-dynamic-range image is obtained by separately acquiring pieces of image data from the high-sensitivity elements 102a and pieces of image data from the low-sensitivity element 102b and merging the pieces of image data. If a luminance difference in an image of a subject is small, the exposure time for the low-sensitivity elements 102b is set to be longer. With the setting, an image higher in resolution than a wide-dynamic-range image is obtained.

SUMMARY

There is a need for an imaging device which achieves both wide-dynamic-range shooting and high-resolution shooting while reducing deterioration in an acquired image.

One non-limiting and exemplary embodiment provides an imaging device as described below.

In one general aspect, the techniques disclosed here feature an imaging device including a counter electrode, a first pixel electrode facing the counter electrode, a second pixel electrode facing the counter electrode, a third pixel electrode facing the counter electrode, a photoelectric conversion layer sandwiched between the first pixel electrode, the second pixel electrode, and the third pixel electrode, and the counter electrode, a first signal detection circuit electrically connected to the first pixel electrode, a second signal detection circuit electrically connected to the second pixel electrode, a first switching element connected between the third pixel electrode and the first signal detection circuit, and a second switching element connected between the third pixel electrode and the second signal detection circuit.

It should be noted that general or specific embodiments may be implemented as an element, a device, an device, a module, a system, an integrated circuit, a method, a computer program, or any selective combination thereof.

Additional benefits and advantages of the disclosed embodiments will become apparent from the specification and drawings. The benefits and/or advantages may be individually obtained by the various embodiments and features of the specification and drawings, which need not all be provided in order to obtain one or more of such benefits and/or advantages.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram schematically showing one example of the circuit configuration of an imaging device according to a first embodiment of the present disclosure;

FIG. 2 is a schematic cross-sectional view showing an exemplary device structure of a pixel cell;

FIG. 3 is a schematic cross-sectional view showing, on an enlarged scale, a photoelectric conversion portion and its vicinity;

FIG. 4 is a schematic plan view when the photoelectric conversion portion is seen from a normal direction of a semiconductor substrate;

FIG. 5 is a schematic cross-sectional view showing, on an enlarged scale, the photoelectric conversion portion and its vicinity after a sensitivity adjustment voltage is changed in the state shown in FIG. 3;

FIG. 6 is a schematic plan view when the photoelectric conversion portion shown in FIG. 5 is seen from the normal direction of the semiconductor substrate;

FIG. 7 is a graph schematically showing the relationship between a sensitivity adjustment voltage and the sensitivity of a pixel cell in a case where a signal charge is a positive hole;

FIG. 8 is a schematic cross-sectional view showing one example of the configuration of a first pixel cell and a second pixel cell in a pixel array of the imaging device;

FIG. 9 is a schematic plan view showing one example of the arrangement of pixel electrodes and auxiliary electrodes when the first pixel cell and the second pixel cell shown in FIG. 8 are seen from the normal direction of the semiconductor substrate;

FIG. 10 is diagram for explaining the operation of the imaging device in a high-resolution mode;

FIG. 11 is a schematic plan view when the photoelectric conversion portion in the state shown in FIG. 10 is seen from the normal direction of the semiconductor substrate;

FIG. 12 is a plan view schematically showing the size of a region Ra in a wide-dynamic-range mode, corresponding to pattern 13 in Table 2;

FIG. 13 is a plan view schematically showing the size of the region Ra in the high-resolution mode, corresponding to pattern 13 in Table 2;

FIG. 14 is a schematic cross-sectional view showing one example of the configuration of a pixel cell in an imaging device according to a second embodiment of the present disclosure;

FIG. 15 is a schematic plan view showing one example of the shapes and arrangement of a first pixel electrode, a second pixel electrode, and a third pixel electrode in the pixel cell shown in FIG. 14;

FIG. 16 is a schematic cross-sectional view showing the pixel cell after connection of a switch Sw3 and connection of a switch Sw4 are changed in the state shown in FIG. 14;

FIG. 17 is a schematic plan view when the pixel cell in the state shown in FIG. 16 is seen from a normal direction of a semiconductor substrate;

FIG. 18 is a schematic cross-sectional view showing one example of the configuration of a pixel cell in an imaging device according to a third embodiment of the present disclosure;

FIG. 19 is a schematic plan view showing one example of the shapes and arrangement of a first pixel electrode and a second pixel electrode in the pixel cell shown in FIG. 18:

FIG. 20 is a schematic cross-sectional view showing the pixel cell after connection of a switch Sw5 and connection of a switch Sw6 are changed in the state shown in FIG. 18;

FIG. 21 is a schematic plan view when the pixel cell in the state shown in FIG. 20 is seen from a normal direction of a semiconductor substrate;

FIG. 22 is a schematic plan view showing one example of the shapes and arrangement of pixel electrodes in an imaging device according to a first modification of the third embodiment of the present disclosure;

FIG. 23 is a schematic plan view showing the one example of the shapes and arrangement of the pixel electrodes in the imaging device according to the first modification of the third embodiment of the present disclosure;

FIG. 24 is a schematic plan view showing one example of the shapes and arrangement of pixel electrodes in an imaging device according to a second modification of the third embodiment of the present disclosure;

FIG. 25 is a schematic plan view showing the one example of the shapes and arrangement of the pixel electrodes in the imaging device according to the second modification of the third embodiment of the present disclosure; and

FIG. 26 is a block diagram showing an exemplary configuration of an imaging module including an imaging device according to an embodiment of the present disclosure.

DETAILED DESCRIPTION

The above-described solid-state imaging device 100 in Japanese Unexamined Patent Application Publication No. 2007-288522 performs control such that the high-sensitivity element 102a and the low-sensitivity element 102b are different in exposure time. The difference in exposure time causes deterioration in image quality. For example, an image obtained when a moving object is shot may have unevenness in illuminance. Additionally, acquisition of a high-resolution image especially entails a longer exposure time, and the time required to acquire an image for one frame (which may be referred to as a “frame rate”) is longer. There is thus a need for an imaging device for achieving both wide-dynamic-range shooting and high-resolution shooting while reducing deterioration in an acquired image.

The overview of one aspect of the present disclosure is as follows.

[Item 1]

An imaging device having a first mode and a second mode, including

a first pixel cell which includes a first pixel electrode, a first signal detection circuit electrically connected to the first pixel electrode, a first auxiliary electrode arranged around the first pixel electrode, a first counter electrode facing the first pixel electrode and the first auxiliary electrode, and a first photoelectric conversion layer arranged between the first pixel electrode and the first auxiliary electrode, and the first counter electrode,

a second pixel cell which includes a second pixel electrode, a second signal detection circuit electrically connected to the second pixel electrode, a second auxiliary electrode arranged around the second pixel electrode, a second counter electrode facing the second pixel electrode and the second auxiliary electrode, and a second photoelectric conversion layer arranged between the second pixel electrode and the second auxiliary electrode, and the second counter electrode, and

a voltage supply circuit which is electrically connected to the first auxiliary electrode and the second auxiliary electrode and supplies a voltage differing between the first mode and the second mode to at least one of the first auxiliary electrode and the second auxiliary electrode.

According to the configuration of Item 1, switching between the two modes can be performed by changing at least one of respective voltages to be applied to the first auxiliary electrode and the second auxiliary electrode.

[Item 2]

The imaging device according to Item 1, in which an electrode area of the first pixel electrode is larger than an electrode area of the second pixel electrode.

According to the configuration of Item 2, the first pixel cell and the second pixel cell can be used as a high-sensitivity cell and a low-sensitivity cell, respectively.

[Item 3]

The imaging device according to Item 1 or 2, in which a minimum value of a distance between the first pixel electrode and the first auxiliary electrode is smaller than a minimum value of a distance between the second pixel electrode and the second auxiliary electrode.

According to the configuration of Item 3, the first pixel cell and the second pixel cell can be used as a high-sensitivity cell and a low-sensitivity cell, respectively.

[Item 4]

The imaging device according to any one of Items 1 to 3, in which the first pixel electrode, the first auxiliary electrode, the second pixel electrode, and the second auxiliary electrode are at a same layer.

According to the configuration of Item 4, complication of a manufacturing process can be avoided.

[Item 5]

The imaging device according to any one of Items 1 to 4, in which the first photoelectric conversion layer and the second photoelectric conversion layer are each a part of a single continuous layer.

According to the configuration of Item 5, complication of a manufacturing process can be avoided.

[Item 6]

The imaging device according to any one of Items 1 to 5, in which the first counter electrode and the second counter electrode are each a part of a single continuous electrode.

According to the configuration of Item 6, complication of a manufacturing process can be avoided.

[Item 7]

The imaging device according to any one of Items 1 to 6, in which

when seen from a direction perpendicular to principal surfaces of the first photoelectric conversion layer and the second photoelectric conversion layer,

the first auxiliary electrode has a first opening portion,

the second auxiliary electrode has a second opening portion,

the first pixel electrode is arranged inside the first opening portion, and

the second pixel electrode is arranged inside the second opening portion.

[Item 8]

An imaging device including

a counter electrode,

a first pixel electrode facing the counter electrode,

a second pixel electrode facing the counter electrode,

a third pixel electrode facing the counter electrode,

a photoelectric conversion layer sandwiched between the first pixel electrode, the second pixel electrode, and the third pixel electrode, and the counter electrode,

a first signal detection circuit electrically connected to the first pixel electrode,

a second signal detection circuit electrically connected to the second pixel electrode,

a first switching element connected between the third pixel electrode and the first signal detection circuit, and

a second switching element connected between the third pixel electrode and the second signal detection circuit.

According to the configuration of Item 8, an area ratio between an electrode (electrodes) connected to the first signal detection circuit and an electrode (electrodes) connected to the second signal detection circuit can be changed in accordance with whether the third pixel electrode is connected to the first pixel electrode or the second pixel electrode. The change in the electrode area ratio allows, for example, switching between a wide-dynamic-range shooting mode and a high-resolution shooting mode.

[Item 9]

The imaging device according to Item 8, in which the first pixel electrode, the second pixel electrode, and the third pixel electrode are at a same layer.

[Item 10]

The imaging device according to Item 8 or 9, in which the first switching element and the second switching element electrically connect the third pixel electrode to either one of the first signal detection circuit and the second signal detection circuit.

[Item 11]

The imaging device according to any one of Items 8 to 10, in which a ratio of a sum of an area of the second pixel electrode and an area of the third pixel electrode to an area of the first pixel electrode is not less than 0.01 and not more than 1.

According to the configuration of Item 11, a ratio between an area of an electrode (electrodes) connected to the first signal detection circuit and an area of an electrode (electrodes) connected to the second signal detection circuit can be brought closer to 1 by connecting the third pixel electrode to the second pixel electrode.

[Item 12]

The imaging device according to any one of Items 8 to 11, further including an auxiliary electrode arranged around the first pixel electrode, the second pixel electrode, and the third pixel electrode.

According to the configuration of Item 12, a charge generated between a pixel in question and a different adjacent pixel can be collected by the auxiliary electrode, and occurrence of color mixing between the pixels can be inhibited.

[Item 13]

The imaging device according to any one of Items 1 to 12, further including a distance measurement circuit which calculates a distance from a subject on the basis of an output from the first signal detection circuit and an output from the second signal detection circuit.

According to the configuration of Item 13, so-called image plane phase detection autofocus can be executed without providing a pixel dedicated to distance measurement in a photosensitive region.

[Item 14]

An imaging module including

an imaging device according to any one of Items 1 to 13, and

a camera signal processing circuit which generates image data on the basis of a pixel signal from the imaging device.

According to the configuration of Item 14, a piece of wide-dynamic-range image data and a piece of high-resolution image data can be acquired with a single device.

Embodiments of the present disclosure will be described below in detail with reference to the drawings. Note that the embodiments described below are all comprehensive or specific examples. Numerical values, shapes, materials, constituent elements, the arrangement and connection forms of the constituent elements, steps, the order of the steps, and the like illustrated in the embodiments below are merely illustrative, and are not intended to limit the present disclosure. Various aspects described in the present specification can be combined as long as there is no contradiction. Among the constituent elements in the embodiments below, those not described in an independent claim representing a top-level concept will be described as optional constituent elements. In the description below, constituent elements having substantially the same functions are denoted by the same reference characters, and a description thereof may be omitted.

First Embodiment

FIG. 1 schematically shows one example of the circuit configuration of an imaging device according to a first embodiment of the present disclosure. An imaging device 100A shown in FIG. 1 includes a plurality of pixel cells 14A and a peripheral circuit. As will be described later in detail, the imaging device 100A is configured to be capable of switching between a wide-dynamic-range mode that allows wide-dynamic-range shooting and a high-resolution mode that allows shooting at a resolution higher than in the wide-dynamic-range mode.

The plurality of pixel cells 14A are, for example, two-dimensionally arrayed on a semiconductor substrate to form a photosensitive region (pixel region). As will be described later, the plurality of pixel cells 14A include first pixel cells which function as high-sensitivity pixel cells in the wide-dynamic-range mode and second pixel cells which function as pixel cells lower in sensitivity than the first pixel cells in the wide-dynamic-range mode. Note that although FIG. 1 shows a configuration with four pixel cells 14A arranged in two rows and two columns, the configuration is merely illustrative. The number and arrangement of pixel cells (pixel cells 14A here) included in the photosensitive region are not limited to those illustrated in FIG. 1.

Each pixel cell 14A includes a photoelectric conversion portion 10, a signal detection transistor 11, a reset transistor 12, and an address transistor (row selection transistor) 13. The signal detection transistor 11, the reset transistor 12, and the address transistor 13 are typically field effect transistors (FETs). Unless otherwise specified, an example will be described below in which an N-channel MOS is used as each of the signal detection transistor 11, the reset transistor 12, and the address transistor 13.

As will be described later in detail with reference to the drawings, the photoelectric conversion portion 10 includes a pixel electrode 50, an auxiliary electrode 61, a counter electrode which faces the pixel electrode 50 and the auxiliary electrode 61, and a photoelectric conversion layer which is arranged between the pixel electrode 50 and the counter electrode. A storage control line 16 which applies a predetermined voltage to the counter electrode of the photoelectric conversion portion 10 when the imaging device 100A is in operation is connected to the photoelectric conversion portion 10 of each pixel cell 14A. The voltage to be supplied to the photoelectric conversion portion 10 via the storage control line 16 can be common to all pixel cells 14A. The voltage to be supplied to the photoelectric conversion portion 10 via the storage control line 16 may be a voltage having fixed magnitude or a time-varying voltage.

The pixel electrode 50 of the photoelectric conversion portion 10 collects, as a signal charge, one of positive and negative charges generated in the photoelectric conversion layer by photoelectric conversion. The auxiliary electrode 61 is configured such that a predetermined voltage can be applied to the auxiliary electrode 61 when the imaging device 100A is in operation. In this example, the auxiliary electrode 61 in each of the plurality of pixel cells 14A constituting the photosensitive region is connected to either one of sensitivity adjustment lines 28 a and 28 b which are connected to a voltage supply circuit 60. The voltage supply circuit 60 supplies predetermined voltages to the auxiliary electrodes 61 via the sensitivity adjustment lines 28 a and 28 b when the imaging device 100A is in operation. As will be described later, the voltage to be applied to the auxiliary electrode 61 may be common to the wide-dynamic-range mode and the high-resolution mode or may differ between the wide-dynamic-range mode and the high-resolution mode.

As will be described later in detail with reference to the drawings, the amount of signal charges captured by the pixel electrode 50 can be adjusted by adjusting the voltage to be applied to the auxiliary electrode 61. In other words, the sensitivity of the pixel cell 14A can be adjusted by adjusting the voltage to be applied to the auxiliary electrode 61. For example, the pixel cell 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 a and the pixel cell 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 b can be made different in sensitivity from each other. Alternatively, the pixel cell 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 a and the pixel cell 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 b can be made uniform in sensitivity with each other.

In the configuration illustrated in FIG. 1, the pixel cell (hereinafter also referred to as a “first pixel cell”) 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 a and the pixel cell (hereinafter also referred to as a “second pixel cell”) 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 b are alternately arranged along a row direction. The pixel cell 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 a and the pixel cell 14A having the auxiliary electrode 61 connected to the sensitivity adjustment line 28 b are also alternately arranged along a column direction. In the present specification, the row direction refers to a direction in which a row extends while the column direction refers to a direction in which a column extends. That is, in FIG. 1, a longitudinal direction on the sheet surface is the column direction, and a lateral direction on the sheet surface is the row direction. The arrangement of the first pixel cells and the second pixel cells is not limited to the example shown in FIG. 1 and can be arbitrarily set.

The voltage supply circuit 60 at least needs to be configured to be capable of causing at least one of a voltage to be supplied to an auxiliary electrode of a first pixel cell and a voltage to be supplied to an auxiliary electrode of a second pixel cell to differ between two modes and is not limited to a particular power circuit. The voltage supply circuit 60 may be a circuit which generates a predetermined voltage or a circuit which transforms a voltage supplied from a different power source into a predetermined voltage. Hereinafter, a voltage which is supplied from the voltage supply circuit 60 to the auxiliary electrode 61 may be referred to as a sensitivity adjustment voltage.

The voltage supply circuit 60 is typically provided as a part of the peripheral circuit outside the photosensitive region. The voltage supply circuit 60 supplies sensitivity adjustment voltages corresponding to an instruction from a user operating the imaging device 100A or an instruction from a different control circuit or the like of the imaging device 100A to the auxiliary electrodes 61 of the pixel cells 14A via the sensitivity adjustment lines 28 a and 28 b. The voltage supply circuit 60 may be a part of a vertical scanning circuit 15 (to be described later). An output from the voltage supply circuit 60 may be supplied to the auxiliary electrodes 61 via the vertical scanning circuit 15.

The pixel electrode 50 of the photoelectric conversion portion 10 is connected to a control terminal (a gate here) of the signal detection transistor 11. Signal charges collected by the pixel electrode 50 are stored in a charge storage node 24 between the pixel electrode 50 and the gate of the signal detection transistor 11. That is, a voltage corresponding to the amount of signal charges stored in the charge storage node 24 is applied to the gate of the signal detection transistor 11. An input (a drain here) of the signal detection transistor 11 is connected to a power line 21 (a source follower power source) which supplies a predetermined power voltage to each pixel cell, and the signal detection transistor 11 outputs a voltage corresponding to the amount of signal charges stored in the charge storage node 24. In other words, the signal detection transistor 11 amplifies and outputs a signal generated by the photoelectric conversion portion 10. The charge storage node 24 between the pixel electrode 50 and the gate of the signal detection transistor 11 is connected to an output (a drain here) of the reset transistor 12.

The address transistor 13 is connected to the signal detection transistor 11. The address transistor 13 is connected between an output (a source here) of the signal detection transistor 11 and one of a plurality of vertical signal lines 17 which are provided for respective columns of a pixel array composed of the plurality of pixel cells 14A. As shown in FIG. 1, a gate of the address transistor 13 is connected to an address signal line 26 which is connected to the vertical scanning circuit (also referred to as a “row scanning circuit”) 15. The vertical scanning circuit 15 selectively reads out pixel signals from the pixel cells 14A to the vertical signal lines 17 on a row-by-row basis by controlling the level of a voltage to be applied to each address signal line 26.

A load circuit 18 and a column signal processing circuit (also referred to as a “row signal storage circuit”) 19 are connected to each of the plurality of vertical signal lines 17. The load circuit 18 and the signal detection transistor 11 form a source follower circuit. The column signal processing circuit 19 performs noise suppression signal processing typified by correlated double sampling, analog-to-digital conversion (AD conversion), and the like. A horizontal signal read circuit (also referred to as a “column scanning circuit”) 20 is connected to the column signal processing circuit 19 that is provided for each column of the pixel array so as to correspond to the vertical signal line 17. The horizontal signal read circuit 20 sequentially reads out signals from the plurality of column signal processing circuits 19 to a horizontal common signal line 29.

In the configuration illustrated in FIG. 1, an inverting amplifier (also referred to as a “feedback amplifier”) 22 is connected between the vertical signal line 17 and the reset transistor 12. As shown in FIG. 1, the vertical signal line 17 is connected to an inverting input terminal of the inverting amplifier 22. When the imaging device 100A is in operation, a predetermined reference voltage Vref is applied to a noninverting input terminal of the inverting amplifier 22. A feedback line 23 is connected to an output terminal of the inverting amplifier 22. As shown in FIG. 1, the feedback line 23 is provided so as to correspond to each column of the pixel array and is connected to an input of the reset transistor 12 of each pixel cell 14A belonging to the column.

A control terminal (a gate here) of the reset transistor 12 is connected to a reset signal line 27. In this example, the reset signal line 27 is connected to the vertical scanning circuit 15. That is, in the example, the vertical scanning circuit 15 selects the pixel cells 14A in the pixel array on a row-by-row basis by controlling a voltage to be applied to each reset signal line 27 and performs signal voltage readout and resetting of the potentials of the pixel electrodes 50. Focus here on a given column of the pixel array. By turning on the reset transistor 12 and the address transistor 13 in one of the pixel cells 14A belonging to the column, a feedback loop including the inverting amplifier 22 can be formed. The formation of the feedback loop allows the potential of the charge storage node 24 in the pixel cell 14A to converge on a potential at which the potential of the vertical signal line 17 is equal to the above-described reference voltage Vref. In this case, an output voltage from the inverting amplifier 22 can be 0 V or a positive voltage close to 0 V. As the reference voltage Vref, an arbitrary voltage within the range from the power voltage (for example, 3.3 V) to ground (0 V) can be used. In other words, an arbitrary voltage within a fixed range (for example, a voltage other than the power voltage) can be used as a reference voltage in resetting.

FIG. 2 schematically shows an exemplary device structure of the pixel cell 14A. In the configuration illustrated in FIG. 2, the photoelectric conversion portion 10 is arranged above a semiconductor substrate 31 on which the signal detection transistor 11, the reset transistor 12, and the address transistor 13 are formed. The semiconductor substrate 31 is not limited to a substrate which is wholly made of a semiconductor and may be an insulating substrate having a semiconductor layer provided on a surface where the photosensitive region is to be formed. An example will be described here in which a P-type silicon (Si) substrate is used as the semiconductor substrate 31. Note that the term “above” in the present specification is used to explain the arrangement of members relative to each other and is not intended to limit the posture of an imaging device when used.

The semiconductor substrate 31 includes impurity regions (N-type regions here) 41A to 41E and an element isolation region 42 for electrical separation between the pixel cells 14A. The impurity region 41A functions as one of a source region and a drain region of the address transistor 13. The impurity region 41B functions as the other of the source region and the drain region of the address transistor 13. The impurity region 41A is connected to the vertical signal line 17 (not shown in FIG. 2, but see FIG. 1). A gate insulating layer 38A and a gate electrode 39A are arranged between the impurity regions 41A and 41B.

In the configuration illustrated in FIG. 2, the impurity region 41B also functions as a source region of the signal detection transistor 11. That is, in this example, the address transistor 13 and the signal detection transistor 11 share the impurity region 41B. The signal detection transistor 11 includes the impurity region 41C as a drain region and a gate insulating layer 38B and a gate electrode 39B which are arranged between the impurity regions 41B and 41C. The impurity region 41C is connected to the power line 21 (not shown in FIG. 2, but see FIG. 1).

The impurity region 41D functions as one of a source region and a drain region of the reset transistor 12. The impurity region 41E functions as the other of the source region and the drain region of the reset transistor 12. The element isolation region 42 is provided between the impurity regions 41C and 41D. The impurity region 41E is connected to the feedback line 23 (not shown in FIG. 2, but see FIG. 1). A gate insulating layer 38C and a gate electrode 39C are arranged between the impurity regions 41D and 41E.

In the shown example, the signal detection transistor 11, the reset transistor 12, and the address transistor 13 are covered with interlayer insulating layers 43A to 43C, and the photoelectric conversion portion 10 is arranged on the interlayer insulating layer 43C. The photoelectric conversion portion 10 includes the pixel electrode 50, the auxiliary electrode 61, a counter electrode 52, and a photoelectric conversion layer 51.

In the shown example, the pixel electrode 50 and the auxiliary electrode 61 are arranged in the interlayer insulating layer 43C. The pixel electrode 50 is electrically separated from the pixel electrode 50 of the different adjacent pixel cell 14A typically through spatial separation. The auxiliary electrode 61 is arranged around the pixel electrode 50. In the example, the pixel electrode 50 and the auxiliary electrode 61 are arranged at the same layer. The pixel electrode 50 and the auxiliary electrode 61 are formed of, for example, a polysilicon that is invested with conductivity by being doped with a metal, such as aluminum or copper, or an impurity. The material for the pixel electrode 50 and that for the auxiliary electrode 61 may be the same or different.

As shown in FIG. 2, the counter electrode 52 faces the pixel electrode 50 and the auxiliary electrode 61. The counter electrode 52 is a transparent electrode which is formed using a conductive transparent material, such as ITO. The counter electrode 52 is connected to the above-described storage control line 16 (see FIG. 1). Thus, the counter electrode 52 is configured such that a predetermined voltage can be applied to the counter electrode 52 when the imaging device 100A is in operation. Note that the term “transparent” in the present specification refers to capable of transmitting at least part of light within a wavelength range as a detection target, and transmitting light within the entire wavelength range (for example, not less than 380 nm and not more than 780 nm) of visible light is not necessarily required. In the present specification, electromagnetic waves in general including infrared rays and ultraviolet rays will be described as “light” for convenience sake. A microlens, a color filter, and the like can be arranged on the counter electrode 52.

The photoelectric conversion layer 51 is arranged between the counter electrode 52, and the pixel electrode 50 and the auxiliary electrode 61. Light incident on the imaging device 100A comes incident on the photoelectric conversion layer 51 via the counter electrode 52. The photoelectric conversion layer 51 is formed of an organic material or an inorganic material, such as amorphous silicon. The photoelectric conversion layer 51 may include a layer made of an organic material and a layer made of an inorganic material. The photoelectric conversion layer 51 irradiated with light generates an electron-hole pair.

Control of the potential of the counter electrode 52 via the storage control line 16 allows the pixel electrode 50 to collect one of positive and negative charges generated by photoelectric conversion as a signal charge. For example, if a positive hole is used as a signal charge, the potential of the counter electrode 52 may be made higher than that of the pixel electrode 50. An example will be described below in which a positive hole is used as a signal charge. Of course, an electron may also be used as a signal charge.

Charges collected by the pixel electrode 50 are stored in a charge storage region including the charge storage node 24 (see FIG. 1). In the example shown in FIG. 2, the pixel electrode 50 is electrically connected to the impurity region 41D as the drain region or the source region of the reset transistor 12 and the gate electrode 39B of the signal detection transistor 11 via pieces 46A to 46C of wiring, plugs 47A to 47C, and contact plugs 45A and 45B. The pixel electrode 50, the pieces 46A to 46C of wiring, the plugs 47A to 47C, the contact plugs 45A and 45B, the impurity region 41D, and the gate electrode 39B constitute the charge storage region that stores signal charges. A signal detection circuit 25 which includes, as a part, the signal detection transistor 11 outputs a signal corresponding to the amount of charges stored in the charge storage region. In this example, the signal detection circuit 25 includes the signal detection transistor 11, the reset transistor 12, and the address transistor 13. Note that the peripheral circuit including the vertical scanning circuit 15, the voltage supply circuit 60, the load circuits 18, the column signal processing circuits 19, the inverting amplifiers 22, the horizontal signal read circuit 20, and the like described above may be formed on the semiconductor substrate 31, like the signal detection circuit 25.

In the configuration illustrated in FIG. 2, the auxiliary electrode 61 arranged around the pixel electrode 50 is connected to a piece 28 of wiring, which is provided in the interlayer insulating layer 43B, via a plug 48 which is provided in the interlayer insulating layer 43C. The piece 28 of wiring is connected to either one of the sensitivity adjustment lines 28 a and 28 b described with reference to FIG. 1. As will be described later, the sensitivity in the pixel cell 14A can be changed by controlling a voltage (hereinafter also referred to as a “sensitivity control voltage”) to be applied to the auxiliary electrode 61.

To manufacture the pixel cell 14A in the imaging device 100A, a general semiconductor manufacturing process can be used. Especially if a silicon substrate is used as the semiconductor substrate 31, various silicon semiconductor processes can be used.

(Alteration of Sensitivity Through Sensitivity Adjustment Voltage Control)

Alteration of the sensitivity in the pixel cell 14A through sensitivity adjustment voltage control will be described below by describing an exemplary operation of the imaging device 100A.

FIG. 3 shows, on an enlarged scale, a cross-section of the photoelectric conversion portion 10 and its vicinity. At the time of image acquisition, the potential of the pixel electrode 50 is first reset. Prior to signal charge storage (which may be referred to as exposure), the reset transistor 12 and the address transistor 13 are turned on. After that, the reset transistor 12 and the address transistor 13 are turned off. With the resetting, the potential of the charge storage node 24 including the pixel electrode 50 is set to a reset voltage (for example, 0 V) as an initial value.

Shooting is performed while a bias voltage is applied to the photoelectric conversion layer 51. At the time of signal charge storage, a predetermined voltage (for example, about 10 V) is being applied to the counter electrode 52 via the storage control line 16. Additionally, in the embodiment of the present disclosure, a sensitivity adjustment voltage is applied from the voltage supply circuit 60 to the auxiliary electrode 61. For example, a voltage (for example, −2 V) lower than the reset voltage (0 V here) is applied as the sensitivity adjustment voltage to the auxiliary electrode 61.

After the reset operation, exposure is performed while predetermined voltages are applied to the counter electrode 52 and the auxiliary electrode 61, respectively. As described above, incidence of light causes the photoelectric conversion layer 51 to generate positive and negative charges. The potential (0 V here) of the pixel electrode 50 and the potential (−2 V here) of the auxiliary electrode 61 are set to be lower than the potential (for example, 10 V) of the counter electrode 52 here. For this reason, of the positive and negative charges generated in the photoelectric conversion layer 51 by photoelectric conversion, the positive charges (typically positive holes) move toward a side where the pixel electrode 50 and the auxiliary electrode 61 are arranged. Of the positive charges generated by photoelectric conversion, charges reaching the pixel electrode 50 are collected by the pixel electrode 50. The charges collected by the pixel electrode 50 are detected as signal charges. Meanwhile, charges reaching the auxiliary electrode 61 are collected by the auxiliary electrode 61. The amount of the signal charges collected by the auxiliary electrode 61 is not reflected in a pixel signal.

The above means that, of light applied to the photoelectric conversion layer 51, light applied to a region 51A is substantially detected. That is, the pixel cell 14A substantially detects, of light incident on an imaging surface, light incident on the region 51A. The region 51A shown in FIG. 3 is a region of the photoelectric conversion layer 51 where signal charges (for example, positive holes) generated by photoelectric conversion are collected mainly by the pixel electrode 50. A region 51B is a region of the photoelectric conversion layer 51 where signal charges generated by photoelectric conversion are collected mainly by the auxiliary electrode 61. In the example described here, a difference (12 V) in potential between the auxiliary electrode 61 and the counter electrode 52 is larger than a difference (10 V) in potential between the pixel electrode 50 and the counter electrode 52. For this reason, generated positive charges are more likely to move toward the auxiliary electrode 61 than toward the pixel electrode 50. As a result, positive charges generated in the region 51A of the photoelectric conversion layer 51 that overlaps with the pixel electrode 50 move mainly to the pixel electrode 50 and are detected as signal charges. Meanwhile, positive charges generated in the region 51B of the photoelectric conversion layer 51 that overlaps with the auxiliary electrode 61 move mainly toward the auxiliary electrode 61 and are collected by the auxiliary electrode 61. Note that a part of the auxiliary electrode 61 which is between two pixel cells functions as a screening electrode which prevents color mixing between adjacent pixel cells

FIG. 4 schematically shows the photoelectric conversion portion 10 when seen from a normal direction of the semiconductor substrate 31. In FIG. 4, the region 51A when the sensitivity adjustment voltage of −2 V is applied to the auxiliary electrode 61 is schematically indicated by a broken line. In the example shown in FIG. 4, the region 51A has a first area slightly larger than the area of the pixel electrode 50 on a plane parallel to the photoelectric conversion layer 51. As shown in FIG. 4, the shape and area of the region 51A when seen from a normal direction of the imaging surface do not necessarily coincide with those of the pixel electrode 50. As will be described later, the shape and/or the area of the region 51A can vary depending on a combination of respective voltages to be applied to the pixel electrode 50, the auxiliary electrode 61, and the counter electrode 52. The shape and area of the region 51B when seen from the normal direction of the imaging surface do not necessarily coincide with those of the auxiliary electrode 61. FIG. 4 schematically shows the region 51A, and there is no definite line of demarcation between the regions 51A and 51B.

Assume that a voltage higher than −2 V is applied as the sensitivity adjustment voltage to the auxiliary electrode 61. For example, assume a case where a voltage (for example, 5 V) lower than the voltage (10 V here) to be applied to the counter electrode 52 and higher than the reset voltage (0 V here) is applied to the auxiliary electrode 61.

FIG. 5 shows, on an enlarged scale, a cross-section of the photoelectric conversion portion 10 and its vicinity when the sensitivity adjustment voltage of 5 V is applied to the auxiliary electrode 61. FIG. 6 schematically shows the photoelectric conversion portion 10 in a state where the sensitivity adjustment voltage of 5 V is applied to the auxiliary electrode 61 when seen from the normal direction of the semiconductor substrate 31.

The present example is the same as the example described with reference to FIGS. 3 and 4 in that positive charges generated in the photoelectric conversion layer 51 by photoelectric conversion move toward the auxiliary electrode 61 and the pixel electrode 50. Note that since the sensitivity adjustment voltage (5 V here) is set to be higher than the reset voltage (0 V here) in the example, positive charges generated at the photoelectric conversion layer 51 are more likely to move toward the pixel electrode 50 than toward the auxiliary electrode 61. For this reason, the amount of positive charges flowing into the auxiliary electrode 61 is smaller in the example than in the example described with reference to FIGS. 3 and 4. As a result, as schematically shown in FIGS. 5 and 6, a region 51C where positive charges movable to the pixel electrode 50 are distributed is larger than the region 51A when the sensitivity adjustment voltage of −2 V is applied to the auxiliary electrode 61. The region 51C, for example, has a second area larger than the first area on the plane parallel to the photoelectric conversion layer 51. A region 51D where positive charges movable to the auxiliary electrode 61 are distributed is smaller than the region 51B when the sensitivity adjustment voltage of −2 V is applied to the auxiliary electrode 61.

As described above, the size of a region (the region 51A or 51C) where signal charges are captured by the pixel electrode 50 can be changed by varying the sensitivity adjustment voltage. In other words, the same effects as those obtained when a light-receiving region in the pixel cell 14A is varied are obtained by varying the sensitivity adjustment voltage. That is, the sensitivity of the pixel cell 14A can be changed by varying the sensitivity adjustment voltage. As can be seen from comparison between FIGS. 3 and 4 and FIGS. 5 and 6, the sensitivity of the pixel cell 14A when the sensitivity adjustment voltage of −2 V is applied to the auxiliary electrode 61 is lower than the sensitivity when the sensitivity adjustment voltage of 5 V is applied to the auxiliary electrode 61.

FIG. 7 schematically shows the relationship between a sensitivity adjustment voltage and the sensitivity of the pixel cell 14A in a case where a signal charge is a positive hole. As shown in FIG. 7, the sensitivity of the pixel cell 14A changes in response to a change in the sensitivity adjustment voltage. For example, if the sensitivity adjustment voltage is increased, the sensitivity increases. As described above, the first embodiment of the present disclosure allows implementation of provision of the imaging device 100A having the variable-sensitivity pixel cells 14A.

Additionally, in the first embodiment of the present disclosure, first pixel cells connected to the sensitivity adjustment line 28 a and second pixel cells connected to the sensitivity adjustment line 28 b are arranged in the photosensitive region. It is thus possible to, for example, apply respective sensitivity adjustment voltages different from each other to the first pixel cells and the second pixel cells. That is, investment of respective different sensitivities to the first pixel cells and the second pixel cells can be relatively easily implemented. A common sensitivity adjustment voltage can, of course, be applied to the first pixel cells and the second pixel cells. An example of mode switching in the imaging device 100A through sensitivity adjustment voltage control will be described below.

(Mode Switching in Imaging Device 100A)

FIG. 8 schematically shows a cross-section of a first pixel cell and a second pixel cell in the pixel array of the imaging device 100A. A first pixel cell 14 a and a second pixel cell 14 b shown in FIG. 8 are examples of the above-described pixel cell 14A. FIG. 8 shows a configuration in which the first pixel cell 14 a and the second pixel cell 14 b are adjacent to each other. The configuration, however, is merely illustrative, and the arrangement of the first pixel cell 14 a and the second pixel cell 14 b in the pixel array can be arbitrarily set. The total number of first pixel cells 14 a and the total number of second pixel cells 14 b in the pixel array need not be equal. Note that the signal detection transistor 11 and the like are not shown in FIG. 8 to avoid excessive complication of FIG. 8. Some members may not be shown in the other drawings.

In the example shown in FIG. 8, the device structures of the first pixel cell 14 a and the second pixel cell 14 b are basically almost the same as the device structure described with reference to FIG. 2. That is, the first pixel cell 14 a includes a pixel electrode 50 a, an auxiliary electrode 61 a, a counter electrode 52 a, a photoelectric conversion layer 51 a, and a first signal detection circuit 25 a. In FIG. 8, an impurity region 41Da which functions as the drain region or the source region of the reset transistor 12 (see FIG. 2) is shown as a part of the first signal detection circuit 25 a. As described above, the impurity region 41Da is electrically connected to the pixel electrode 50 a. The auxiliary electrode 61 a of the first pixel cell 14 a is connected to the sensitivity adjustment line 28 a. Meanwhile, the second pixel cell 14 b includes a pixel electrode 50 b, an auxiliary electrode 61 b, a counter electrode 52 b, a photoelectric conversion layer 51 b, and a second signal detection circuit 25 b. The second signal detection circuit 25 b includes, as a part, an impurity region 41Db which is electrically connected to the pixel electrode 50 b. The auxiliary electrode 61 b is connected to the sensitivity adjustment line 28 b. As described with reference to FIG. 1, the sensitivity adjustment lines 28 a and 28 b are connected to the voltage supply circuit 60.

In the configuration illustrated in FIG. 8, the counter electrode 52 a of the first pixel cell 14 a and the counter electrode 52 b of the second pixel cell 14 b are parts of a single continuous electrode. As described above, the counter electrodes 52 a and 52 b need not be separate from each other. A common voltage can be applied to a plurality of first pixel cells 14 a and a plurality of second pixel cells 14 b at a time by forming a counter electrode (the counter electrodes 52 a and 52 b here) over a plurality of pixel cells, as shown in FIG. 8. Of course, if a desired voltage can be applied via the storage control line 16, counter electrodes of two pixel cells adjacent to each other may be spatially separate from each other. For example, the counter electrodes 52 a and 52 b may be spatially separate.

The photoelectric conversion layer 51 a of the first pixel cell 14 a and the photoelectric conversion layer 51 b of the second pixel cell 14 b constitute parts of a single continuous photoelectric conversion layer here. Obviously, for example, photoelectric conversion layers of two pixel cells adjacent to each other may be spatially separate from each other. In FIG. 8, a region Ra indicated by a broken line schematically represents a region where signal charges generated by photoelectric conversion are collected mainly by the pixel electrode 50 a, and a region Rb schematically represents a region where signal charges generated by photoelectric conversion are collected mainly by the pixel electrode 50 b.

The pixel electrode 50 a, the auxiliary electrode 61 a, the pixel electrode 50 b, and the auxiliary electrode 61 b are arranged at the same layer here. Thus, the pixel electrode 50 a, the auxiliary electrode 61 a, the pixel electrode 50 b, and the auxiliary electrode 61 b can be collectively formed by, for example, adopting a common material for the electrodes.

FIG. 9 shows one example of the arrangement of the pixel electrode 50 a, the auxiliary electrode 61 a, the pixel electrode 50 b, and the auxiliary electrode 61 b when seen from the normal direction of the semiconductor substrate 31. In the configuration illustrated in FIG. 9, the auxiliary electrode 61 a has an opening portion Apa at the center, and the pixel electrode 50 a is arranged inside the opening portion Apa. In other words, the auxiliary electrode 61 a is arranged around the pixel electrode 50 a so as to surround the pixel electrode 50 a. A void having a dimension Ga is formed between the auxiliary electrode 61 a and the pixel electrode 50 a. Similarly, in the example shown in FIG. 9, the auxiliary electrode 61 b has an opening portion Apb at the center, and the pixel electrode 50 b is arranged inside the opening portion Apb. A void having a dimension Gb is formed between the auxiliary electrode 61 b and the pixel electrode 50 b. In the example, a minimum value of the distance Ga between the auxiliary electrode 61 a and the pixel electrode 50 a is smaller than a minimum value of the distance Gb between the auxiliary electrode 61 b and the pixel electrode 50 b.

Note that there is no definite line of demarcation between a plurality of pixel cells on an imaging surface. Note that each pixel cell can be regarded as a region corresponding to the outer shape of an auxiliary electrode in a case as shown in FIG. 9 where an auxiliary electrode (for example, the auxiliary electrode 61 a) is arranged around a pixel electrode (for example, the pixel electrode 50 a). In the example, the sizes of the auxiliary electrodes 61 a and 61 b are almost the same, and the sizes of the first pixel cell 14 a and the second pixel cell 14 b are thus almost the same. The sizes of the auxiliary electrodes 61 a and 61 b may, of course, be different from each other.

As shown in FIG. 9, in the example described here, the electrode area of the pixel electrode 50 a of the first pixel cell 14 a is larger than the electrode area of the pixel electrode 50 b of the second pixel cell 14 b. The term “electrode area” in the present specification refers to the area of an electrode when seen from a normal direction of a substrate (the semiconductor substrate 31 here) supporting the photoelectric conversion portion 10. Note that a normal direction of a principal plane of the photoelectric conversion layer 51 is typically substantially parallel to the normal direction of the substrate.

Refer back to FIG. 8. In the configuration illustrated in FIG. 8, the voltage supply circuit 60 includes switches Sw1 and Sw2 and a voltage source for a voltage V1 and a voltage source for a voltage V2. The specific configuration of the voltage supply circuit 60, of course, is not limited to the configuration illustrated in FIG. 8. The voltages V1 and V2 are sensitivity adjustment voltages which satisfy the relationship V1<V2 and are lower than a voltage to be applied to the counter electrodes 52 a and 52 b. For example, the voltage V1 can be a voltage (for example, −2 V) lower than the reset voltage (for example, 0 V). The voltage V2 can be a voltage (for example, 5 V) higher than the reset voltage.

FIG. 8 shows a state in which the sensitivity adjustment lines 28 a and 28 b are connected to the voltage source for the voltage V1 via the switches Sw1 and Sw2. Since the sensitivity adjustment lines 28 a and 28 b are both connected to the voltage source for the voltage V1, the common voltage V1 is supplied to the auxiliary electrode 61 a of the first pixel cell 14 a and the auxiliary electrode 61 b of the second pixel cell 14 b. Thus, in the state shown in FIG. 8, a difference in potential between the counter electrode 52 a and the auxiliary electrode 61 a and a difference in potential between the counter electrode 52 b and the auxiliary electrode 61 b are equal to each other. Since the reset voltage is typically common to the first pixel cell 14 a and the second pixel cell 14 b, a difference in potential between the counter electrode 52 a and the pixel electrode 50 a and a difference in potential between the counter electrode 52 b and the pixel electrode 50 b are equal to each other. That is, it can be said that, in the state shown in FIG. 8, there is no difference between the first pixel cell 14 a and the second pixel cell 14 b except for the electrode area of a pixel electrode.

As described above, the electrode area of the pixel electrode 50 a is larger than that of the pixel electrode 50 b here. For this reason, as schematically shown in FIGS. 8 and 9, the area of the region Ra is larger than that of the region Rb. That is, under the same level of irradiation, the pixel electrode 50 a can collect more signal charges than the pixel electrode 50 b. In other words, the sensitivity of the first pixel cell 14 a is higher than that of the second pixel cell 14 b, and the first pixel cell 14 a and the second pixel cell 14 b can be used as a high-sensitivity cell and a low-sensitivity cell, respectively. As described above, arrangement of a plurality of pixel cells having respective pixel electrodes different in electrode area from each other in a pixel array and application of a common sensitivity adjustment voltage to respective auxiliary electrodes of the plurality of pixel cells allow achievement of a sensitivity ratio, corresponding to the electrode area ratio between the pixel electrodes, between the plurality of pixel cells.

A pixel signal from the first pixel cell 14 a as a high-sensitivity cell can be said to be an image signal less prone to blocked up shadows, and a pixel signal from the second pixel cell 14 b as a low-sensitivity cell can be said to be an image signal less prone to blown out highlights. Two pieces of image data different in sensitivity can be obtained in shooting a single scene by acquiring a pixel signal from the first pixel cell 14 a as a high-sensitivity cell and a pixel signal from the second pixel cell 14 b as a low-sensitivity cell via the first signal detection circuit 25 a and the second signal detection circuit 25 b, respectively. Merging of such two pieces of image data allows formation of an image free from blown out highlights and blocked up shadows of a scene with a high contrast ratio. Formation of such an image is called “high dynamic range imaging”. As described above, the embodiment of the present disclosure allows acquisition of image data for high dynamic range imaging without performing shooting a plurality of times. That is, wide-dynamic-range shooting is possible.

According to the first embodiment, since different exposure times need not be adopted for a high-sensitivity cell and a low-sensitivity cell (an electronic shutter need not be operated at different times for a high-sensitivity cell and a low-sensitivity cell) in wide-dynamic-range shooting, two scanning circuits corresponding to a high-sensitivity cell and a low-sensitivity cell need not be provided. Additionally, the sensitivity ratio between a high-sensitivity cell and a low-sensitivity cell can be finely adjusted by finely adjusting respective sensitivity adjustment voltages for a high-sensitivity cell and a low-sensitivity cell.

Additionally, the mode of the imaging device 100A can be switched to the high-resolution mode that allows shooting at a resolution higher than in the wide-dynamic-range mode by changing sensitivity adjustment voltages to be supplied to the auxiliary electrode 61 a of the first pixel cell 14 a and the auxiliary electrode 61 b of the second pixel cell 14 b from the state shown in FIG. 8 to another state.

FIG. 10 is a diagram for explaining the operation of the imaging device 100A in the high-resolution mode. FIG. 11 schematically shows the photoelectric conversion portion 10 in the state shown in FIG. 10 when seen from the normal direction of the semiconductor substrate 31. Respective sensitivity adjustment voltages different from each other can be applied to the auxiliary electrode 61 a of the first pixel cell 14 a and the auxiliary electrode 61 b of the second pixel cell 14 b by changing connection of the switch Sw1 from the state shown in FIG. 8 to the state shown in FIG. 10. In this example, the voltages V1 and V2 are applied to the auxiliary electrodes 61 a and 61 b, respectively, by changing the connection of the switch Sw1.

Focus on the second pixel cell 14 b. As compared with the state shown in FIG. 8, a higher sensitivity adjustment voltage (the voltage V2 here) is applied to the auxiliary electrode 61 b. Thus, more signal charges (for example, positive holes) are collected by the auxiliary electrode 61 b, and, as a result, the region Rb is larger than in the state shown in FIG. 8. That is, the same effects as those obtained when a light-receiving region is expanded are obtained, and the sensitivity of the second pixel cell 14 b is higher than in the state shown in FIG. 8. Note that the range of change in the size of a region (the region Rb here) where signal charges are captured by the pixel electrode 50 b that can be adjusted by varying the sensitivity adjustment voltage can be increased with an increase in the distance Gb between the pixel electrode 50 b and the auxiliary electrode 61 b.

In this case, the area of the region Ra in the first pixel cell 14 a and the area of the region Rb in the second pixel cell 14 b can be made almost equal, as schematically shown in FIG. 11, by appropriately selecting respective values for the voltages V1 and V2 in accordance with an electrode area ratio. That is, the sensitivity in the second pixel cell 14 b can be made closer to that in the first pixel cell 14 a through sensitivity adjustment voltage control. In this case, the function of the first pixel cell 14 a and the function of the second pixel cell 14 b can be said to be almost equivalent. Thus, for example, if the number of first pixel cells 14 a is equal to the number of second pixel cells 14 b in the pixel array, resolution can be made twice that in the wide-dynamic-range mode by narrowing a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b and making the sensitivities of the first pixel cell 14 a and the second pixel cell 14 b uniform. As described above, the first embodiment of the present disclosure allows switching between the wide-dynamic-range mode and the high-resolution mode through sensitivity adjustment voltage control.

In the high-resolution mode in the embodiment of the present disclosure, a piece of image data for one frame can be acquired by one shooting operation, as compared with a method adopting different exposure times for a high-sensitivity element and a low-sensitivity element, like the technique described in Japanese Unexamined Patent Application Publication No. 2007-288522. Thus, an exposure time for a low-sensitivity element need not be extended, and a frame rate is not reduced. High-resolution shooting according to the embodiment of the present disclosure is suitable for shooting of an object moving at high speed. Short-exposure pixels and long-exposure pixels are not coexistent in an image obtained by high-resolution shooting according to the embodiment of the present disclosure. This allows inhibition of occurrence of blurring or the like due to coexistence of pixels different in exposure time to inhibit image deterioration. Note that a difference in sensitivity between a high-sensitivity cell and a low-sensitivity cell can also be narrowed by arranging high-sensitivity cells and low-sensitivity cells in a pixel array and selectively amplifying a pixel signal acquired by each low-sensitivity cell using an amplifier circuit. However, such a method amplifies noise in a pixel signal from a low-sensitivity cell, and an S/N ratio decreases. According to the embodiment of the present disclosure, selective amplification of a pixel signal from a low-sensitivity cell is unnecessary, and such a decrease in S/N ratio does not occur.

In the high-resolution mode, for example, a set of the first pixel cell 14 a and the second pixel cell 14 b adjacent to each other can be used as a set of pixels for phase detection autofocus (AF). That is, a plurality of sets of the first pixel cell 14 a and the second pixel cell 14 b adjacent to each other can be arranged in the pixel array, and an output from the first pixel cell 14 a and an output from the second pixel cell 14 b in each set can be used for phase difference detection. The imaging device 100A may include a distance measurement circuit which calculates the distance between the imaging surface and a subject on the basis of outputs from the first pixel cells 14 a and outputs from the second pixel cells 14 b. Note that the first pixel cell 14 a and the second pixel cell 14 b as a set used for phase difference detection need not be adjacent to each other in the pixel array.

The set of the first pixel cell 14 a and the second pixel cell 14 b that functions as pixel cells for phase difference detection in the high-resolution mode is used to acquire pixel signals used for high dynamic range imaging in the wide-dynamic-range mode. Thus, according to the embodiment of the present disclosure, phase difference detection can be performed by effectively using pixel cells in a pixel array without arrangement of pixels used only for phase difference detection on an imaging surface. For example, if the pixel cell 14A (that is, the first pixel cell 14 a) connected to the sensitivity adjustment line 28 a and the pixel cell 14A (that is, the second pixel cell 14 b) connected to the sensitivity adjustment line 28 b are alternately arranged along rows and columns of the pixel array, as shown in FIG. 1, the number and positions of sets of the first pixel cell 14 a and the second pixel cell 14 b used for phase difference detection can be arbitrarily changed in accordance with a shooting scene.

Note that, if wiring is installed such that a sensitivity adjustment voltage independent of and different from one for the auxiliary electrodes 61 a of other first pixel cells 14 a is applied to the auxiliary electrodes 61 a of some first pixel cells 14 a in the pixel array and such that a sensitivity adjustment voltage independent of and different from one for the auxiliary electrodes 61 b of other second pixel cells 14 b is applied to the auxiliary electrodes 61 b of the second pixel cells 14 b adjacent to the first pixel cells 14 a, phase difference detection can also be performed in the wide-dynamic-range mode.

Obviously, a combination of sensitivity adjustment voltages to be supplied to the auxiliary electrode 61 a of the first pixel cell 14 a and the auxiliary electrode 61 b of the second pixel cell 14 b is not limited to the above-described examples. Table 1 below shows examples of a combination of the sensitivity adjustment voltages to be supplied to the auxiliary electrode 61 a of the first pixel cell 14 a and the auxiliary electrode 61 b of the second pixel cell 14 b.

TABLE 1 (Electrode area of pixel Wide-dynamic-range mode electrode 50a) ≠ First pixel Second pixel High-resolution mode (electrode area cell (high- cell (low- First Second of pixel sensitivity sensitivity pixel pixel electrode 50b) cell) cell) cell cell Pattern 1 V2 V2 V1 (↓) V2 Pattern 2 V3 (↑) V2 V1 (↓) V2 Pattern 3 V2 V1 (↓) V1 (↓) V2 Pattern 4 V3 (↑) V1 (↓) V1 (↓) V2 Pattern 5 V2 V2 V2 V3 (↑) Pattern 6 V3 (↑) V2 V2 V3 (↑) Pattern 7 V2 V1 (↓) V2 V3 (↑) Pattern 8 V3 (↑) V1 (↓) V2 V3 (↑) Pattern 9 V2 V2 V1 (↓) V3 (↑) Pattern 10 V3 (↑) V2 V1 (↓) V3 (↑) Pattern 11 V2 V1 (↓) V1 (↓) V3 (↑) Pattern 12 V3 (↑) V1 (↓) V1 (↓) V3 (↑)

In Table 1, patterns 1 to 4 are voltage application patterns which reduce the sensitivity of the first pixel cell 14 a by supplying a sensitivity adjustment voltage (the voltage V1 here) relatively lower than the voltage V2 as a reference to the auxiliary electrode 61 a of the first pixel cell 14 a to narrow a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b, in the high-resolution mode. Note that a down arrow in parentheses in Table 1 means a reduction in sensitivity while an up arrow means an increase in sensitivity.

In pattern 1 in Table 1, the sensitivity adjustment voltage to be supplied to the auxiliary electrode 61 a of the first pixel cell 14 a and the sensitivity adjustment voltage to be supplied to the auxiliary electrode 61 b of the second pixel cell 14 b are set to a common sensitivity adjustment voltage (the voltage V2 here) in the wide-dynamic-range mode. However, for example, a voltage V3 higher than the voltage V2 may be supplied to the auxiliary electrode 61 a of the first pixel cell 14 a in the wide-dynamic-range mode, as indicated in pattern 2. The voltage V3 here is a sensitivity adjustment voltage lower than a voltage to be applied to the counter electrodes 52 a and 52 b, like the voltages V1 and V2. Specific values of the voltages V1, V2, and V3 may be appropriately determined in accordance with the electrode structures of the first pixel cell 14 a and the second pixel cell 14 b. Since if the voltage V3 is supplied to the auxiliary electrode 61 a of the first pixel cell 14 a, the region Ra can be made larger than in a state where the voltage V2 is applied to the auxiliary electrode 61 a, the sensitivity of the first pixel cell 14 a is higher than when the voltage V2 is applied to the auxiliary electrode 61 a of the first pixel cell 14 a. That is, a difference in the sensitivity of the first pixel cell 14 a between the wide-dynamic-range mode and the high-resolution mode can be made larger than in pattern 1. Thus, a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b in the wide-dynamic-range mode can be made larger.

Like pattern 3, the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b in one of the wide-dynamic-range mode and the high-resolution mode may be the reverse of those in the other. To interchange the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b at the time of switching between the two modes, switching from the high-resolution mode to the wide-dynamic-range mode may be performed by, for example, changing a connection destination of the switch Sw1 and a connection destination of the switch Sw2 in the state shown in FIG. 10 (corresponding to the high-resolution mode) to the voltage source for the voltage V1 and the voltage source for the voltage V2, respectively. Alternatively, a combination of sensitivity adjustment voltages which increases the sensitivity of the first pixel cell 14 a and reduces the sensitivity of the second pixel cell 14 b in the wide-dynamic-range mode, as in pattern 4, may be adopted.

In Table 1, patterns 5 to 8 are voltage application patterns which increase the sensitivity of the second pixel cell 14 b by supplying a sensitivity adjustment voltage (the voltage V3 here) relatively higher than the voltage V2 as the reference to the auxiliary electrode 61 b of the second pixel cell 14 b to narrow a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b, in the high-resolution mode. In Table 1, the row of pattern 5 corresponds to the way the sensitivity adjustment voltages are applied in the wide-dynamic-range mode and in the high-resolution mode in the example described with reference to FIGS. 8 to 11. A voltage application pattern as in patterns 5 to 8 which narrows a difference in sensitivity between a high-sensitivity cell and a low-sensitivity cell in the high-resolution mode by increasing the sensitivity of a low-sensitivity cell is advantageous over a voltage application pattern as in patterns 1 to 4 described above which narrows a difference in sensitivity between a high-sensitivity cell and a low-sensitivity cell in the high-resolution mode by reducing the sensitivity of a high-sensitivity cell because a reduction in frame rate can be curbed. From the viewpoint of widening a difference in the sensitivity of the second pixel cell 14 b between the wide-dynamic-range mode and the high-resolution mode, pattern 7 among the four patterns can be considered more effective.

In Table 1, patterns 9 to 12 are voltage application patterns which narrow a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b using a combination of sensitivity adjustment voltages that reduces the sensitivity of the first pixel cell 14 a and increases the sensitivity of the second pixel cell 14 b in the high-resolution mode. In patterns 2 and 7 described above, either one of the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b is fixed both in the wide-dynamic-range mode and in the high-resolution mode. In contrast, in pattern 12, the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b in one of the wide-dynamic-range mode and the high-resolution mode are set to the reverse of those in the other, using the voltage V1 lower than the voltage V2 and the voltage V3 higher than the voltage V2. From the viewpoint of securing a wider dynamic range in the wide-dynamic-range mode, a more potent effect can be expected to be obtained by adopting pattern 12 among patterns 1 to 12 shown in Table 1.

As shown in Table 1, one or both of the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b may be made to differ between the wide-dynamic-range mode and the high-resolution mode. According to the first embodiment, a relatively high sensitivity ratio (for example, 100:1) can be achieved between a high-sensitivity cell and a low-sensitivity cell in the wide-dynamic-range mode.

In the example described here, a difference in sensitivity is made between the first pixel cell 14 a and the second pixel cell 14 b in the wide-dynamic-range mode by making the electrode area of the pixel electrode 50 a in the first pixel cell 14 a and that of the pixel electrode 50 b in the second pixel cell 14 b different. The present disclosure, however, is not limited to the example. A difference in sensitivity may be made between the first pixel cell 14 a and the second pixel cell 14 b in the wide-dynamic-range mode by, for example, making the size of the auxiliary electrode 61 a and that of the auxiliary electrode 61 b different. That is, the first pixel cell 14 a and the second pixel cell 14 b may be different in size from each other.

Alternatively, the electrode area of the pixel electrode 50 a in the first pixel cell 14 a and that of the pixel electrode 50 b in the second pixel cell 14 b may be set to a common electrode area. Table 2 below shows examples of a combination of the sensitivity adjustment voltages to be supplied to the auxiliary electrode 61 a of the first pixel cell 14 a and the auxiliary electrode 61 b of the second pixel cell 14 b in a configuration in which the electrode area of the pixel electrode 50 a in the first pixel cell 14 a and that of the pixel electrode 50 b in the second pixel cell 14 b are set to a common electrode area.

TABLE 2 (Electrode area of pixel Wide-dynamic-range mode electrode 50a) = First pixel Second pixel High-resolution mode (electrode area cell (high- cell (low- First Second of pixel sensitivity sensitivity pixel pixel electrode 50b) cell) cell) cell cell Pattern 13 V3 (↑) V2 V2 V2 Pattern 14 V2 V1 (↓) V2 V2 Pattern 15 V3 (↑) V1 (↓) V2 V2

If the electrode area of the pixel electrode 50 a is equal to that of the pixel electrode 50 b, it can be said that the first pixel cell 14 a and the second pixel cell 14 b are substantially no different in device structure except that the first pixel cell 14 a and the second pixel cell 14 b are configured such that respective sensitivity adjustment voltages different from each other can be independently applied to the auxiliary electrodes 61 a and 61 b. Thus, if the electrode area of the pixel electrode 50 a is equal to that of the pixel electrode 50 b, the high-resolution mode can be implemented by setting the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b to a common sensitivity adjustment voltage.

In Table 2, pattern 13 makes a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b in the wide-dynamic-range mode by making the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a relatively higher. FIGS. 12 and 13 schematically show the region Ra in the high-resolution mode and the region Ra in the wide-dynamic-range mode, respectively, corresponding to pattern 13 in Table 2. In the state shown in FIG. 12, the area of the region Ra is almost equal to that of the region Rb. In the state shown in FIG. 13, the area of the region Ra is larger than that of the region Rb.

In Table 2, pattern 14 makes a difference in sensitivity between the first pixel cell 14 a and the second pixel cell 14 b in the wide-dynamic-range mode by making the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b relatively lower. Like pattern 15, the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 a of the first pixel cell 14 a may be made relatively higher and the sensitivity adjustment voltage to be applied to the auxiliary electrode 61 b of the second pixel cell 14 b may be made relatively lower in the wide-dynamic-range mode than in the high-resolution mode. From the viewpoint of securing a wider dynamic range in the wide-dynamic-range mode, adoption of pattern 15 among patterns 13 to 15 shown in Table 2 is considered more effective.

In the examples shown in FIGS. 8 to 13, the pixel electrode 50 a and the auxiliary electrode 61 a have rectangular outer shapes. The shapes of the pixel electrode 50 a and the auxiliary electrode 61 a, however, are not limited to these. For example, the outer shapes of the pixel electrode 50 a and the auxiliary electrode 61 a may each be a circular shape, an elliptical shape, a polygonal shape, or the like. The outer shape of the pixel electrode 50 a and that of the auxiliary electrode 61 a need not be the same. In the examples, the auxiliary electrode 61 a is formed as a single continuous electrode. The configuration, however, is merely illustrative. For example, the auxiliary electrode 61 a may be composed of a plurality of spatially separated sub-auxiliary electrodes. What is said for the pixel electrode 50 a and the auxiliary electrode 61 a of the first pixel cell 14 a also applies to the pixel electrode 50 b and the auxiliary electrode 61 b of the second pixel cell 14 b.

Second Embodiment

FIG. 14 schematically shows a cross-section of a pixel cell in an imaging device according to a second embodiment of the present disclosure. An imaging device 100B shown in FIG. 14 includes a plurality of pixel cells 14B. The plurality of pixel cells 14B are arranged, for example, in a matrix in a photosensitive region, like the pixel cells 14A described above. The imaging device 100B is also capable of switching between a wide-dynamic-range mode that allows wide-dynamic-range shooting and a high-resolution mode that allows shooting at a resolution higher than in the wide-dynamic-range mode, like the imaging device 100A described above.

As shown in FIG. 14, the pixel cell 14B includes a photoelectric conversion layer 51 and a counter electrode 52 which faces one of principal surfaces of the photoelectric conversion layer 51. The photoelectric conversion layer 51 and the counter electrode 52 are typically formed to extend over the plurality of pixel cells 14B. The pixel cell 14B includes a first signal detection circuit 25 a, a first pixel electrode 50 x, a second signal detection circuit 25 b, a second pixel electrode 50 y, and a third pixel electrode 50 z which is arranged between the first pixel electrode 50 x and the second pixel electrode 50 y. In the example shown in FIG. 14, the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z are arranged at the same layer and are arranged on one of the principal surfaces of the photoelectric conversion layer 51, the one being on the side without the counter electrode 52.

Each of the first signal detection circuit 25 a and the second signal detection circuit 25 b can have the same configuration as that of the signal detection circuit 25 described with reference to FIG. 2. An impurity region 41Da of the first signal detection circuit 25 a which functions as a drain region or a source region of a reset transistor in the first signal detection circuit 25 a and an impurity region 41Db of the second signal detection circuit 25 b which functions as a drain region or a source region of a reset transistor in the second signal detection circuit 25 b are shown here. As shown in FIG. 14, the impurity regions 41Da and 41Db are electrically separated by providing an element isolation region 42 between the impurity regions 41Da and 41Db.

As schematically shown in FIG. 14, the first signal detection circuit 25 a is connected to the first pixel electrode 50 x, and the second signal detection circuit 25 b is connected to the second pixel electrode 50 y. Signal charges collected by the first pixel electrode 50 x are stored in a charge storage region which includes, as a part, the impurity region 41Da, and a pixel signal corresponding to the amount of stored signal charges is read out via a vertical signal line 17 corresponding to the first signal detection circuit 25 a. Similarly, signal charges collected by the second pixel electrode 50 y are stored in a charge storage region which includes, as a part, the impurity region 41Db, and a pixel signal corresponding to the amount of stored signal charges is read out via the vertical signal line 17 corresponding to the second signal detection circuit 25 b. That is, the pixel cell 14B is connected to the two vertical signal lines 17. One of the two vertical signal lines 17 outputs a signal corresponding to signal charges collected by the first pixel electrode 50 x, and the other vertical signal line 17 outputs a signal corresponding to signal charges collected by the second pixel electrode 50 y.

As shown in FIG. 14, the pixel cell 14B further includes a switching circuit 64. The switching circuit 64 is configured to be capable of switching between electrical connection of the third pixel electrode 50 z to the first pixel electrode 50 x and electrical connection of the third pixel electrode 50 z to the second pixel electrode 50 y.

The switching circuit 64 typically includes one or more switching elements. In the configuration illustrated in FIG. 14, the switching circuit 64 includes a switch Sw3 which is connected between the first pixel electrode 50 x and the third pixel electrode 50 z and a switch Sw4 which is connected between the second pixel electrode 50 y and the third pixel electrode 50 z. The switching circuit 64 switches between electrical connection of the first pixel electrode 50 x and the third pixel electrode 50 z and electrical connection of the second pixel electrode 50 y and the third pixel electrode 50 z by turning on and off the switches Sw3 and Sw4. The switches Sw3 and Sw4 are typically field effect transistors which are formed on a semiconductor substrate 31. The switches Sw1 to Sw4 according to the present disclosure, of course, are not limited to field effect transistors. Note that the switches Sw3 and Sw4 are shown in FIG. 14 using circuit symbols for convenience sake to avoid excessive complication of FIG. 14. FIG. 14 shows a state in which the third pixel electrode 50 z is connected to the first pixel electrode 50 x. In this state, the second pixel electrode 50 y is electrically separated from the first pixel electrode 50 x and the third pixel electrode 50 z.

In the example shown in FIG. 14, the pixel cell 14B includes an auxiliary electrode 61 which is arranged around the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z. In the shown example, the auxiliary electrode 61 is arranged at the same layer as the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z. When the imaging device 100B is in operation, a predetermined voltage is supplied to the auxiliary electrode 61. Since the auxiliary electrode 61 is arranged so as to surround the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z, color mixing between the pixel cells 14B adjacent to each other can be inhibited. In the second embodiment, different voltages need not be adopted as respective voltages to be applied to the auxiliary electrode 61 for the wide-dynamic-range mode and the high-resolution mode. The auxiliary electrodes 61 of the plurality of pixel cells 14B may be integrally formed.

FIG. 15 shows one example of the shapes and arrangement of the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z when seen from a normal direction of the semiconductor substrate 31. FIG. 15 illustrates a configuration in which the electrode area ratio between the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z is set to 5:4:1.

In a state in which the switches Sw3 and Sw4 are turned on and off, respectively, the first pixel electrode 50 x and the third pixel electrode 50 z are electrically connected. In this state, the ratio between the electrode area (the sum of the electrode area of the first pixel electrode 50 x and that of the third pixel electrode 50 z here) of an electrode (electrodes) electrically connected to the first signal detection circuit 25 a and the electrode area (the electrode area of the second pixel electrode 50 y here) of an electrode (electrodes) electrically connected to the second signal detection circuit 25 b is 9:1. Thus, under the same level of irradiation, signal charges can be stored in a charge storage region including the first pixel electrode 50 x and in a charge storage region including the second pixel electrode 50 y in a ratio corresponding to the electrode area ratio. A region R1 indicated by a thick broken line in FIG. 15 schematically represents a region of the photoelectric conversion layer 51 where signal charges (for example, positive holes) generated by photoelectric conversion are collected mainly by the first pixel electrode 50 x and the third pixel electrode 50 z. A region R2 schematically represents a region where signal charges are collected mainly by the second pixel electrode 50 y. The area ratio between the regions R1 and R2 is approximately 9:1.

The same effects as those obtained when two sub-pixel cells different in sensitivity from each other are arranged inside the pixel cell 14B are obtained by arranging the third pixel electrode 50 z between the first pixel electrode 50 x and the second pixel electrode 50 y and connecting the third pixel electrode 50 z to the first pixel electrode 50 x, as described above. That is, a sub-pixel cell (a left-hand region of the pixel cell 14B here) including the first signal detection circuit 25 a can be used as a high-sensitivity cell, and a sub-pixel cell (a right-hand region of the pixel cell 14B here) including the second signal detection circuit 25 b can be used as a low-sensitivity cell. Two pieces of image data different in sensitivity can be acquired in shooting of a single scene by individually acquiring an output from the first signal detection circuit 25 a and an output from the second signal detection circuit 25 b. Like the first embodiment, the present embodiment is capable of wide-dynamic-range shooting.

FIGS. 16 and 17 schematically show a state after connection of the switch Sw3 and connection of the switch Sw4 are changed in the state shown in FIG. 14. As schematically shown in FIG. 16, it is possible to dissolve the connection between the first pixel electrode 50 x and the third pixel electrode 50 z and electrically connect the second pixel electrode 50 y and the third pixel electrode 50 z by turning off and on the switches Sw3 and Sw4, respectively. Since the electrode area ratio between the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z is 5:4:1, the ratio between the electrode area of an electrode (electrodes) (the electrode area of the first pixel electrode 50 x here) electrically connected to the first signal detection circuit 25 a and the electrode area of an electrode (electrodes) (the sum of the electrode area of the second pixel electrode 50 y and that of the third pixel electrode 50 z here) electrically connected to the second signal detection circuit 25 b is 5:5. That is, the area of a region R3 where signal charges (for example, positive holes) generated by photoelectric conversion are collected mainly by the first pixel electrode 50 x and the area of a region R4 where signal charges are collected mainly by the second pixel electrode 50 y and the third pixel electrode 50 z can be made almost equal. In other words, it is possible to make a difference in sensitivity between a sub-pixel cell (a left-hand region of the pixel cell 14B here) including the first signal detection circuit 25 a and a sub-pixel cell (a right-hand region of the pixel cell 14B here) including the second signal detection circuit 25 b effectively 0.

In this example, the ratio of the sum of the electrode area of the second pixel electrode 50 y and that of the third pixel electrode 50 z to the electrode area of the first pixel electrode 50 x is almost 1. The ratio of the sum of the electrode area of the second pixel electrode 50 y and that of the third pixel electrode 50 z to the electrode area of the first pixel electrode 50 x is not limited to the example and may be, for example, not less than 0.01 and not more than 1. The lower limit of 0.01 here subsumes a value which can be regarded as substantially 0.01. The upper limit of 1 here subsumes a value which can be regarded as substantially 1.

The same effects as those obtained when two sub-pixel cells equivalent in sensitivity are arranged in the pixel cell 14B are obtained by changing the connection of the switch Sw3 and the connection of the switch Sw4, as described above. Thus, an output from the first signal detection circuit 25 a and an output from the second signal detection circuit 25 b can be treated as equivalent, and an image having a resolution twice that in the wide-dynamic-range mode is obtained on the basis of the outputs. That is, switching to the high-resolution mode can be implemented by changing the connection of the switch Sw3 and the connection of the switch Sw4.

In the second embodiment, the auxiliary electrode 61 is typically not arranged between the first pixel electrode 50 x and the second pixel electrode 50 y. Thus, as compared with a configuration in which the auxiliary electrode 61 is arranged between the first pixel electrode 50 x and the second pixel electrode 50 y, signal charges collected by the auxiliary electrode 61 can be reduced. This allows effective utilization of signal charges generated by photoelectric conversion. Note that the number of third pixel electrodes 50 z included in one pixel cell 14B is not limited to 1. The pixel cell 14B can include two or more third pixel electrodes 50 z. Variations of a sensitivity ratio can be increased by increasing the number of third pixel electrodes 50 z included in one pixel cell 14B. The shapes of the first pixel electrode 50 x, the second pixel electrode 50 y, and the third pixel electrode 50 z are not limited to the shown example.

In the state shown in FIGS. 16 and 17, a pixel signal corresponding to light incident on a left-half region of the pixel cell 14B is output from the first signal detection circuit 25 a, and a pixel signal corresponding to light incident on a right-half region of the pixel cell 14B is output from the second signal detection circuit 25 b. As described above, in the high-resolution mode, an output from the first signal detection circuit 25 a and an output from the second signal detection circuit 25 b can be treated as equivalent. Thus, phase difference detection can be performed using an output from the first signal detection circuit 25 a and an output from the second signal detection circuit 25 b, like the first embodiment. According to the second embodiment, phase difference detection can be performed by effectively using pixel cells in a pixel array, like the first embodiment.

Third Embodiment

FIG. 18 schematically shows a cross-section of a pixel cell in an imaging device according to a third embodiment of the present disclosure. An imaging device 100C shown in FIG. 18 includes a plurality of pixel cells 14C. Note that the plurality of pixel cells 14C are arranged, for example, in a matrix in a photosensitive region, like the pixel cells 14A and 14B described above. The imaging device 100C can obtain a higher-resolution image through computation on the basis of images taken in two operating modes.

As shown in FIG. 18, the pixel cell 14C includes a photoelectric conversion layer 51 and a counter electrode 52 which faces one of principal surfaces of the photoelectric conversion layer 51. The photoelectric conversion layer 51 and the counter electrode 52 are typically formed to extend over the plurality of pixel cells 14C. The pixel cell 14C includes a signal detection circuit 25, a first pixel electrode 50 s, and a second pixel electrode 50 t. In the example shown in FIG. 18, the first pixel electrode 50 s and the second pixel electrode 50 t are arranged at the same layer and are arranged on one of the principal surfaces of the photoelectric conversion layer 51, the one being on the side without the counter electrode 52.

The signal detection circuit 25 can have the same configuration as that of the signal detection circuit 25 described with reference to FIG. 2. An impurity region 41D which functions as a drain region or a source region of a reset transistor in the signal detection circuit 25 is shown here. As shown in FIG. 18, two adjacent pixel cells 14C are electrically separated by an element isolation region 42.

As schematically shown in FIG. 18, the signal detection circuit 25 is connected to the second pixel electrode 50 t. Signal charges collected by the second pixel electrode 50 t are stored in a charge storage region which includes, as a part, the impurity region 41D, and a pixel signal corresponding to the amount of stored signal charges is read out via a vertical signal line 17 (not shown in FIG. 18) corresponding to the signal detection circuit 25.

As shown in FIG. 18, the pixel cell 14C further includes a switching circuit 64. The switching circuit 64 is configured to be capable of switching between electrical connection of the first pixel electrode 50 s to the second pixel electrode 50 t of the same pixel cell 14C and electrical connection of the first pixel electrode 50 s to the second pixel electrode 50 t within the adjacent pixel cell 14C.

The switching circuit 64 typically includes one or more switching elements. In the configuration illustrated in FIG. 18, the switching circuit 64 includes a switch Sw5 which is connected between the first pixel electrode 50 s and the second pixel electrode 50 t of the same pixel cell 14C and a switch Sw6 which is connected between the first pixel electrode 50 s and the second pixel electrode 50 t of the adjacent pixel cell 14C. The switching circuit 64 switches between electrical connection of the first pixel electrode 50 s to the second pixel electrode 50 t of the same pixel cell 14C and electrical connection of the first pixel electrode 50 s to the second pixel electrode 50 t of the adjacent pixel cell 14C by turning on and off the switches Sw5 and Sw6. The switches Sw5 and Sw6 are typically field effect transistors which are formed on a semiconductor substrate 31. The switches Sw5 and Sw6 according to the present disclosure, of course, are not limited to field effect transistors. Note that the switches Sw5 and Sw6 are shown in FIG. 18 using circuit symbols for convenience sake to avoid excessive complication of FIG. 18. FIG. 18 shows a state in which the first pixel electrode 50 s is connected to the second pixel electrode 50 t of the same pixel cell 14C. In this state, the first pixel electrode 50 s is electrically separated from the adjacent second pixel electrode 50 t.

FIG. 19 shows one example of the shapes and arrangement of the first pixel electrode 50 s and the second pixel electrode 50 t when seen from a normal direction of the semiconductor substrate 31. FIG. 19 illustrates a configuration in which the electrode area ratio between the first pixel electrode 50 s and the second pixel electrode 50 t is set to 1:1.

In a state where the switches Sw5 and Sw6 are turned on and off, respectively, the first pixel electrode 50 s and the second pixel electrode 50 t of the same pixel cell 14C are electrically connected. In this state, signal charges collected by the first pixel electrode 50 s and the second pixel electrode 50 t within the same pixel cell 14C are read out by the signal detection circuit 25. A region R5 indicated by a thick broken line in FIG. 19 schematically represents a region of the photoelectric conversion layer 51 where signal charges (for example, positive holes) generated by photoelectric conversion are collected by the first pixel electrode 50 s and the second pixel electrode 50 t within the same pixel cell 14C.

FIGS. 20 and 21 schematically show a state after connection of the switch Sw5 and connection of the switch Sw6 are changed in the state shown in FIG. 18. As schematically shown in FIG. 20, it is possible to dissolve the connection between the first pixel electrode 50 s and the second pixel electrode 50 t within the same pixel cell 14C and electrically connect the second pixel electrode 50 t and the first pixel electrode 50 s of the adjacent pixel cell 14C by turning off and on the switches Sw5 and Sw6, respectively. In this state, signal charges collected by the second pixel electrode 50 t and the first pixel electrode 50 s of the adjacent pixel cell 14C are read out by the signal detection circuit 25. A region R6 indicated by a thick broken line in FIG. 21 schematically represents a region of the photoelectric conversion layer 51 where signal charges (for example, positive holes) generated by photoelectric conversion are collected by the second pixel electrode 50 t and the first pixel electrode 50 s of the adjacent pixel cell 14C.

As can be seen from comparison between FIGS. 19 and 21, the position of a unit pixel of an image is shifted by changing the connection of the switch Sw5 and the connection of the switch Sw6. That is, the region R6 is shifted from the region R5 by a half-pixel in a lateral direction. A higher-resolution image can be obtained through computation by acquiring such images having unit pixel positions shifted from each other.

(First Modification of Third Embodiment)

FIG. 22 shows the arrangement of pixel electrodes in a color imaging device according to the present modification when seen from a normal direction of the semiconductor substrate 31. As shown in FIG. 22, a pixel cell 14D includes four pixel electrodes in two rows and two columns which are adjacent to one another, and a plurality of pixel cells 14D are arranged in a matrix. Any one of a green filter (G1), a green filter (G2), a blue filter (B), and a red filter (R) is regularly arranged for each pixel 14D.

The cross-section structure of the pixel cell 14D is basically the same as in the third embodiment shown in FIG. 18. A description of the cross-section structure will be omitted, and differences will be described. The pixel cell 14D includes a signal detection circuit, a first pixel electrode 70 a, a second pixel electrode 70 b, a third pixel electrode 70 c, and a fourth pixel electrode 70 d. The signal detection circuit is connected to the fourth pixel electrode 70 d.

The pixel cell 14D includes a switching circuit. The switching circuit is configured to be capable of switching between electrical connection of the fourth pixel electrode 70 d to the first pixel electrode 70 a, the second pixel electrode 70 b, and the third pixel electrode 70 c within the same pixel cell 14D and electrical connection of the fourth pixel electrode 70 d to pixel electrodes 70 e, 70 f, and 70 g of the different pixel cells 14D. More specifically, a switch is provided between the fourth pixel electrode 70 d and each of the first pixel electrode 70 a, the second pixel electrode 70 b, the third pixel electrode 70 c, the pixel electrode 70 e, the pixel electrode 70 f, and the pixel electrode 70 g.

In a first operating mode, the fourth pixel electrode 70 d is electrically connected to the first pixel electrode 70 a, the second pixel electrode 70 b, and the third pixel electrode 70 c within the same pixel cell 14D. In this case, a region R7 indicated by a thick broken line in FIG. 22 is a unit pixel of an image. In a second operating mode, the fourth pixel electrode 70 d is electrically connected to the pixel electrodes 70 e, 70 f, and 70 g of the different pixel cells 14D, for which green filters are arranged. In this case, a region R8 indicated by thick broken lines in FIG. 23 is a unit pixel of an image.

The first operating mode and the second operating mode are different in the center position of four pixel electrodes to be connected together. That is, as shown in FIGS. 22 and 23, a center position in the first operating mode is at a point A, and a center position in the second operating mode is at a point B.

In the first operating mode, since a green filter is arranged for the pixel cell 14D, red and blue light signals cannot be directly obtained at the pixel cell 14D. For example, to obtain a piece of blue image information at the position of the pixel cell 14D, a piece of image information of a blue pixel cell located around the pixel cell 14D is extracted, and interpolation is performed using the piece of image information. For example, a piece of blue image information can be interpolated at the pixel cell 14D using, for example, a piece of information of a blue pixel cell which is a right-hand neighbor of the pixel cell 14D or a blue pixel cell which is located obliquely below the pixel cell 14D.

In the present modification, the second operating mode allows acquisition of pieces of image information of each color at positions different from in the first operating mode. For example, a pixel electrode which is located at the bottom right of a blue pixel cell which is a right-hand neighbor of the pixel cell 14D is electrically connected to three pixel electrodes of different blue pixel cells centered around a point C in the second operating mode. With this connection, a piece of blue image information can be obtained at the position of the point C. Thus, interpolation using an additional piece of blue image information obtained in the second operating mode allows finer interpolation of pieces of blue image information than interpolation only in the first operating mode.

As has been described above, in the present modification, two images different in the center position of a unit pixel from each other can be obtained by imaging in the first operating mode and in the second operating mode. Since the images are different in the center position of a unit pixel from each other, an image having an increased resolution can be obtained through computation based on the images.

(Second Modification of Third Embodiment)

FIG. 24 shows the arrangement of pixel electrodes in an imaging device according to the present modification when seen from a normal direction of a semiconductor substrate. As shown in FIG. 24, a pixel cell 14E includes six pixel electrodes, pixel electrodes 511 a to 511 f. A plurality of pixel cells 14E are arranged in a matrix.

The cross-section structure of the pixel cell 14E is basically the same as in the third embodiment shown in FIG. 18. A description of the cross-section structure will be omitted, and differences will be described. The pixel cell 14E includes two signal detection circuits and the pixel electrodes 511 a to 511 f. One of the two signal detection circuits is connected to the pixel electrode 511 a while the other is connected to the pixel electrode 511 f.

The pixel cell 14E includes a switching circuit. The switching circuit is configured to be capable of switching between electrical connections of the pixel electrodes 511 b, 511 c, 511 d, and 511 e to the pixel electrode 511 a adjacent thereto and electrical connections of the pixel electrodes 511 b, 511 c, 511 d, and 511 e to the pixel electrode 511 f adjacent thereto. More specifically, switches are provided between the pixel electrode 511 a and each of the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto and between the pixel electrode 511 f and each of the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto.

In a first operating mode, the pixel electrode 511 a is electrically connected to the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto. The pixel electrode 511 f is electrically insulated from the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto. In this state, signal charges collected by the pixel electrodes 511 a, 511 b, 511 c, 511 d, and 511 e within the same pixel cell 14E are read out by the signal detection circuit connected to the pixel electrode 511 a. Signal charges collected by the pixel electrode 511 f are read out by the signal detection circuit connected to the pixel electrode 511 f. A region R9 indicated by a thick broken line in FIG. 24 schematically represents a region of a photoelectric conversion layer where signal charges (for example, positive holes) generated by photoelectric conversion are collected by the pixel electrodes 511 a, 511 b, 511 c, 511 d, and 511 e within the same pixel cell 14E. A region R10 indicated by a thick broken line in FIG. 24 schematically represents a region of the photoelectric conversion layer where signal charges (for example, positive holes) generated by photoelectric conversion are collected by the pixel electrode 511 f. In the first operating mode, the shape and area of the region R9 can be made almost equal to those of the region R10. In other words, a difference in sensitivity between a sub-pixel cell including the pixel electrode 511 a and a sub-pixel cell including the pixel electrode 511 f can be made effectively 0.

In a second operating mode, the pixel electrode 511 f is electrically connected to the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto. The pixel electrodes 511 b, 511 d, and 511 e connected to the pixel electrode 511 f here are each included in the different pixel cell 14E adjacent to the pixel cell 14E, to which the pixel electrode 511 f belongs. The pixel electrode 511 a is electrically insulated from the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto. In this state, signal charges collected by the pixel electrode 511 f and the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto are read out by the signal detection circuit connected to the pixel electrode 511 f. Signal charges collected by the pixel electrode 511 a are read out by the signal detection circuit connected to the pixel electrode 511 a. A region R11 indicated by a thick broken line in FIG. 25 schematically represents a region of the photoelectric conversion layer where signal charges (for example, positive holes) generated by photoelectric conversion are collected by the pixel electrode 511 a. A region R12 indicated by a thick broken line in FIG. 25 schematically represents a region of the photoelectric conversion layer where signal charges (for example, positive holes) generated by photoelectric conversion are collected by the pixel electrode 511 f and the pixel electrodes 511 b, 511 c, 511 d, and 511 e adjacent thereto. In the second operating mode, a difference in area between the regions R11 and R12 can be made. In other words, a sub-pixel cell including the pixel electrode 511 a can be used as a low-sensitivity cell, and a sub-pixel cell including the pixel electrode 511 f can be used as a high-sensitivity cell. Thus, in the second operating mode, two pieces of image data different in sensitivity can be simultaneously acquired. Like the first embodiment, wide-dynamic-range shooting is possible.

As has been described above, in the first operating mode, unit pixels identical in sensitivity are densely aligned, and a high-resolution image can be obtained by image processing. In the second operating mode, a wide-dynamic-range image can be obtained by merging signals from unit pixels different in sensitivity.

(Imaging Module)

FIG. 26 shows an exemplary configuration of an imaging module including an imaging device according to an embodiment of the present disclosure. An imaging module 200 shown in FIG. 26 includes an imaging device 100, an optical system 110 which includes a lens, a diaphragm, and the like, a camera signal processing circuit 120, and a system controller 130. The imaging module 200 may include an input interface including various buttons and a touch screen for accepting an input from a user.

As the imaging device 100, the imaging device 100A or the imaging device 100B described above can be used. In the configuration illustrated in FIG. 26, the imaging device 100 includes a distance measurement circuit 105. The distance measurement circuit 105 is, for example, a microcomputer. The distance measurement circuit 105 acquires outputs from a first signal detection circuit 25 a and a second signal detection circuit 25 b and calculates the distance between an imaging surface and a subject on the basis of the outputs.

The camera signal processing circuit 120 is composed of a semiconductor element or the like and generates image data by processing a pixel signal output from the imaging device 100. For example, the camera signal processing circuit 120 executes high dynamic range imaging on the basis of an output from the imaging device 100 in a wide-dynamic-range mode. A specific method for high dynamic range imaging is not limited to a particular method, and various signal processing methods used for high dynamic range imaging can be applied.

Provision of the camera signal processing circuit 120 can be implemented using a digital signal processor (DSP), an image signal processor (ISP), a field-programmable gate array (FPGA), or the like. The camera signal processing circuit 120 can include one or more memories. The camera signal processing circuit 120 is not limited to a processing circuit dedicated to high dynamic range imaging and high-resolution image formation. High dynamic range imaging and/or high-resolution image formation may be implemented by a combination of a general-purpose processing circuit and a program in which necessary processing is described. The program can be stored in a memory in the camera signal processing circuit 120, a memory in the system controller 130, or the like.

The system controller 130 is typically a semiconductor integrated circuit, such as a CPU, and controls portions in the imaging module 200. The system controller 130 can include one or more memories. The system controller 130 may include, as a part, the above-described distance measurement circuit 105.

The system controller 130 controls, for example, driving of a vertical scanning circuit 15, driving of the distance measurement circuit 105, switching of voltages to be applied from a voltage supply circuit 60 to sensitivity adjustment lines 28 a and 28 b, switching of connection in a switching circuit 64, and the like. The system controller 130, for example, receives a signal from the input interface and notifies the voltage supply circuit 60 of the voltages to be applied to the sensitivity adjustment lines 28 a and 28 b. Alternatively, the system controller 130 switches the connection in the switching circuit 64. That is, the system controller 130 executes switching between the wide-dynamic-range mode and a high-resolution mode. The system controller 130 may judge a range of illuminance in a subject on the basis of outputs from a first signal detection circuit 25 a and a second signal detection circuit 25 b and execute switching to the high-resolution mode.

As has been described above, according to the embodiments of the present disclosure, control of a sensitivity adjustment voltage to be applied to an auxiliary electrode allows switching between the wide-dynamic-range mode and the high-resolution mode. In addition to the above-described examples, various alterations may be made to an imaging device according to an embodiment of the present disclosure. For example, each of the signal detection transistor 11, the reset transistor 12, and the address transistor 13 may be an N-channel MOS or a P-channel MOS. It is not necessary that all the transistors are N-channel MOSs or P-channel MOSs. At least one of the signal detection transistor 11, the reset transistor 12, and the address transistor 13 may be a bipolar transistor.

An imaging device according to the present disclosure is useful in, for example, an image sensor or a digital camera. An imaging device according to the present disclosure can be used in a medical camera, a camera for a robot, a security camera, a camera used while being mounted on a vehicle, or the like. 

What is claimed is:
 1. An imaging device comprising: a counter electrode; a first pixel electrode facing the counter electrode; a second pixel electrode facing the counter electrode; a third pixel electrode facing the counter electrode; a photoelectric conversion layer sandwiched between the first pixel electrode, the second pixel electrode, and the third pixel electrode, and the counter electrode; a first signal detection circuit electrically connected to the first pixel electrode; a second signal detection circuit electrically connected to the second pixel electrode; a first switching element connected between the third pixel electrode and the first signal detection circuit; and a second switching element connected between the third pixel electrode and the second signal detection circuit.
 2. The imaging device according to claim 1, wherein the first pixel electrode, the second pixel electrode, and the third pixel electrode are located in a same layer.
 3. The imaging device according to claim 1, wherein the first switching element and the second switching element electrically connect the third pixel electrode to either one of the first signal detection circuit and the second signal detection circuit.
 4. The imaging device according to claim 1, wherein a ratio of a sum of an area of the second pixel electrode and an area of the third pixel electrode to an area of the first pixel electrode is 0.01 or more and 1 or less.
 5. The imaging device according to claim 1, further comprising: an auxiliary electrode located around the first pixel electrode, the second pixel electrode, and the third pixel electrode.
 6. The imaging device according to claim 1, further comprising: a distance measurement circuit that calculates a distance from a subject on the basis of an output from the first signal detection circuit and an output from the second signal detection circuit.
 7. An imaging module comprising: an imaging device according to claim 1; and a camera signal processing circuit, wherein the imaging device outputs a pixel signal on the basis of an output from the first signal detection circuit and an output from the second signal detection circuit, and the camera signal processing circuit generates image data on the basis of the pixel signal. 